Low profile brooder

ABSTRACT

A low profile brooder is provided, comprising a venturi, a burner base, a burner cap, and a baffle. The burner base and the burner cap reside adjacent to each other, with the burner cap disposed above the burner base and with a distribution chamber between them. A central axis is defined. A venturi resides below the burner base and is in fluid communication with the distribution chamber at the central axis. The venturi defines a fuel flow path between its upstream and downstream ends. The fuel flow path resides at least partially at one or more of an acute angle, a perpendicular angle, and an obtuse angle to the central axis. A baffle resides in the distribution chamber between the central axis and the periphery.

CROSS REFERENCE TO RELATED APPLICATIONS

This application is a continuation of, and claims the benefit ofpriority to, U.S. application Ser. No. 17/014,238, filed Sep. 8, 2020.

STATEMENT REGARDING FEDERALLY SPONSORED RESEARCH OR DEVELOPMENT

Not applicable.

THE NAMES OF PARTIES TO A JOINT RESEARCH AGREEMENT

Not applicable.

INCORPORATION-BY-REFERENCE OF MATERIALS SUBMITTED ON A COMPACT DISC ORAS A TEXT FILE VIA THE OFFICE ELECTRONIC FILING SYSTEM

Not applicable.

STATEMENT REGARDING PRIOR DISCLOSURES BY THE INVENTOR OR A JOINTINVENTOR

Not applicable.

BACKGROUND OF THE INVENTION Field of the Invention

The present invention relates to a brooder having a minimized verticalprofile and, more particularly, to a brooder with a non-vertical fuelmixing tube and with a baffle in the fuel distribution chamber tooptimize the heating distribution.

Description of the Related Art

The poultry industry uses heaters within poultry houses to raise theinterior temperature to levels more favorable for the growth andwell-being of the birds therein. Such a heater is referred to in thepoultry industry as a brooder.

Typically, a plurality of brooders are suspended from overhead,positioned relatively closely above the flock to provide the bestheating for the birds.

An archetypal brooder is fired by gas fuel. Various fuels are used,including natural gas, propane, butane, and liquefied petroleum gas.

A brooder includes a venturi, also known as a mixing tube, in which thegas fuel mixes with ambient air. The fuel and air mixture is conveyed bythe venturi to a burner, which sometimes comprises a burner base and aburner cap. That burner often includes corrugations, scalloping, orapertures proximate to or around its perimeter, forming multiple burnerports. At the burner ports, the fuel and air mixture is ignited. Theburning fuel heats an emitter located adjacent to and above the burnerports. The flame wicks along the inner side of the emitter where ittransfers heat through conduction, radiation, and combustion byproducttransmission through convection. To maximize the efficiency of thebrooder, the flame shape emerging from each burner port (or burnersection of any shape) needs to be precisely proportioned, which can onlybe accomplished by tightly controlling the amount of fuel emerging fromeach burner port. If the flame is too short, it will be unable toeffectively realize the heat transfers previously mentioned, whichresults in relatively cooler surfaces on the emitter that can be seenfrom the outside as a non-equal, non-uniform glow on the emittersurface. If the flame is too long, it will impinge on the emittersurface and result in poor combustion of the fuel, creating excessiveamounts of carbon monoxide, and further will overheat the emitterresulting in reduced lifespan of the components. The heated emitterwarms the interior of the poultry house by radiant heat transfer. Acanopy is located above the emitter, which reflects heat from theemitter back downwardly toward the flock.

Typically, a brooder's venturi is oriented vertically. This usualvertical orientation provides an advantage in that the fuel and airmixture thereby delivered to the burner has substantially the samevelocity across the venturi downstream end cross-section and thus tendsto be symmetrically distributed to the perimeter burner ports, which inturn provides the most efficient heating to the emitter and thus themost efficient use of the fuel to heating the interior of the poultryhouse.

The vertical orientation of the brooder's venturi causes a disadvantage,however, inasmuch as it adds to the vertical height of the brooder. Theventuri must be of a length adequate to allow sufficient mixing of thefuel and air between the venturi's upstream end and its downstream end,and therefore cannot be arbitrarily shortened. As noted, for optimalpoultry farming, a brooder in use should be close to the poultry.However, gathering the birds for removal from the poultry house, oncethey have matured and are ready for further processing, usually involvesthe use of machinery, or if not then the work of humans, within theinterior of the poultry house. Such gathering prerequires raising thebrooders within a poultry house to try to allow for sufficient clearanceand operation of the machinery and/or movement of humans. But the addedbrooder dimension from the vertical venturi increases the risk ofinterference with the gathering machinery and/or creates obstacles forworkers within the poultry house.

It would thus be an improvement to provide a brooder with a minimizedvertical profile. However, reducing the vertical profile of a brooder byorienting the venturi in other than a vertical path risks causing anasymmetrical heating pattern upon the emitter and consequent suboptimalheating and suboptimal use of fuel. For a non-vertical venturi toconnect to a horizontal burner base, the fuel flow path must turn. Thatturn causes the fuel and air mixture to exit the non-vertical venturi,and to enter the burner, at unequal velocities across the cross-sectionof the downstream end of the non-vertical venturi as a consequence ofthe fluid dynamics of the path of the mixture having turned. Thus thevolume of the fuel and air mixture that passes out of the non-verticalventuri and into the burner, per unit of time, differs across thecross-section of the downstream end of the non-vertical venturi. Thediffering velocities and flow rate of the fuel and air mixture, if notcorrected, causes the flames emerging from the burner ports to beunequal. Because the flame is in communication with an emitter, which ispositioned at a precise, equal distance from the burner ports, the flamesize from each port must be precisely proportioned. Only when the flamesemerging from the burner ports are all of the same length can an even,uniform, and optimum heating of the emitter be achieved. Such an optimalresult cannot be accomplished with a non-vertical venturi unless thediffering velocities and flow rate of the fuel and air mixture conveyedto the burner from the non-vertical venturi are equalized.

In view of the foregoing, it would be desirable to provide a brooderwith a nonvertical venturi and thus a lower vertical profile, yet stillachieve uniform heating of the emitter. It would be also be desirablefor such a brooder with a lower vertical profile to have uniform emitterheating even with different fuels, such as natural gas, propane, butane,and liquefied petroleum gas. Ideally, such a brooder would maximize theuse of existing components, such as the canopy, emitter, burner cap, andburner base, both to save redesign costs and to enable easier repairsand/or component replacement. Of course, minimizing the expense of sucha design would be an advantage. And, recognizing that poultry housestend to be dusty environments and that therefore brooders thereinrequire periodic cleaning such as by air blowers, preferably such abrooder would have simplified, easy-to-clean components.

In view of the foregoing, the present invention relates to animprovement upon the known systems and methods of brooders, and providesdistinct advantages over the conventional systems and methods.

BRIEF SUMMARY OF THE INVENTION

A low profile brooder is provided. As revealed in the followingdescription and the figures herein, this invention discovers a minimizedvertical brooder profile having an equal, uniform heating of the emitterin a simplified, efficient design. This invention achieves suchperformance even with different fuels, maximizes the use of existingcomponents, and is simplified and easy to clean. This inventiondiscovers that, to accomplish such functionality with the use of anon-vertical venturi, the needed precision in flame size controlrequires a purposely configured and positioned baffle interacting withthe fuel and air mixture flow to each burner port.

In accordance with certain aspects of certain embodiments of the presenttechnology, a low profile brooder may comprise a burner base, the burnerbase having an upper surface and an opposing lower surface, and defininga central axis. A venturi with an upstream end and a downstream end maybe disposed with its downstream end proximate the lower surface of theburner base. The venturi may define a fuel flow path between theupstream end and the downstream end, the fuel flow path residing atleast partially at an angle divergent from the central axis. The broodermay include a baffle, the baffle residing proximate to the upper surfaceof the burner base. Additionally and/or alternatively, in variousembodiments one or more of the following features may also be included:

-   -   (a) the fuel flow path may reside at least in part radial to the        central axis, the radiant defining a first polar direction from        the central axis;    -   (b) the baffle may be attached to the upper surface at a        location in the first polar direction from the central axis;    -   (c) the baffle may be attached to the upper surface;    -   (d) the baffle may include a lower opening;    -   (e) the baffle may be at least partially planar, the at least        partial plane disposed perpendicular to a radiant extending from        the central axis; and/or    -   (f) the baffle may be rectangular and further may include first        and second corner chamfers.

In accordance with additional aspects of other embodiments of thepresent technology, a low profile brooder may comprise a burner base,the burner base defining a central axis. A distribution chamber may bedefined above the burner base. A baffle may reside in the distributionchamber. A venturi may at least in part extend away from the centralaxis, the venturi being in fluid communication with the burner base atthe central axis. Additionally and/or alternatively, in variousembodiments one or more of the following features may also be included:

-   -   (a) the baffle may be attached to the burner base;    -   (b) the venturi may extend away from the central axis at least        in part in a first direction, and the baffle may reside apart        from the central axis and in the first direction from the        central axis;    -   (c) the venturi may extend away from the central axis at least        in part in a first direction, the baffle may be at least        partially planar, the baffle may reside in the distribution        chamber apart from the central axis in the first direction from        the central axis, and the at least partial plane may be        perpendicular to a radiant from the central axis;    -   (d) the baffle may be at least partially planar, the at least        partial plane being parallel to the central axis;    -   (e) the baffle may be at least partially planar, may be        rectangular, and may include first and second chamfered upper        corners; and/or    -   (f) the baffle may include a lower opening proximate the burner        base.

In accordance with still further aspects of other embodiments of thepresent technology, a low profile brooder may comprise a venturi, aburner base, a burner cap, and a baffle. The burner base and the burnercap may reside adjacent to each other, with the burner cap disposedabove the burner base, may define a central axis, and may define betweenthem a distribution chamber. The burner base and the burner cap may alsodefine a periphery, the periphery defining a burner port. A venturi mayalso be included, residing below the burner base and in fluidcommunication with the distribution chamber at the central axis. Theventuri may have an upstream end and a downstream end, and may define afuel flow path between the upstream end and the downstream end. The fuelflow path may reside at least partially at one or more of an acuteangle, a perpendicular angle, and an obtuse angle to the central axis. Abaffle may reside in the distribution chamber between the central axisand the periphery. Additionally and/or alternatively, in variousembodiments one or more of the following features may also be included:

-   -   (a) the baffle is attached to the burner base.    -   (b) the baffle is perpendicular to at least a portion of the        burner base.    -   (c) the baffle is at least partially parallel to the central        axis.    -   (d) the baffle includes a panel, the panel being at least        partially planar, and the at least partial baffle plane is        disposed perpendicular to a radiant extending between the        central axis and the periphery.    -   (e) the baffle includes a lower opening and opposing upper        corner chamfers.

Additional advantages of the invention will be set forth in part in thedescription that follows, and in part will be obvious from thedescription, or may be learned by practice of the invention. Theadvantages of the invention will be realized and attained by means ofthe elements and combinations particularly pointed out in the appendedclaims. It is to be understood that both the foregoing generaldescription and the following detailed description are exemplary andexplanatory only and are not restrictive of the invention, as claimed.

The purpose of the Abstract hereinabove is to enable the United StatesPatent and Trademark Office, and the public generally, to determinequickly from a cursory inspection the nature of the technicaldisclosure. The Abstract is not provided for interpreting the scope ofthe claims herein, nor to define the invention or the application, norto be limiting in any way as to the scope of the invention.

BRIEF DESCRIPTION OF THE DRAWINGS

The details of the present invention, as to both its structure and itsoperation, can be understood with reference to the accompanyingdrawings, in which:

FIG. 1 is a side elevation view of a low profile brooder according to anembodiment of the present invention;

FIG. 2 is a perspective view, from a lower perspective, of a low profilebrooder according to an embodiment of the present invention;

FIG. 3 is an exploded perspective view of a low profile brooderaccording to an embodiment of the present invention;

FIG. 4 is a cross-sectional view, taken at A:A in FIG. 1 , of a canopy,emitter, burner cap, burner base, and venturi of a low profile brooderaccording to an embodiment of the present invention;

FIG. 5 is a perspective view of a venturi, burner base, and baffle of alow profile brooder according to an embodiment of the present invention;

FIG. 6 is a top plan view of a venturi, burner base, and baffle of a lowprofile brooder according to an embodiment of the present invention;

FIG. 7 is a side elevation view of a venturi, burner base, and baffle ofa low profile brooder according to an embodiment of the presentinvention; and

FIG. 8 is a perspective view of a baffle of a low profile brooderaccording to an embodiment of the present invention.

It should be noted that the drawings discussed above and below are notto scale in all instances, but may have exaggerated dimensions in somerespect to illustrate the principles of the invention.

DETAILED DESCRIPTION OF REPRESENTATIVE EMBODIMENTS

Reference will now be made in detail to the presently preferredembodiments of the invention, one or more examples of which areillustrated in the drawings. Each example is provided by way ofexplanation of the invention, and is not meant as a limitation of theinvention. For example, features illustrated or described as part of oneembodiment may be used with a second embodiment to yield a thirdembodiment. It is intended that the present application include suchmodifications and variations as come within the scope and spirit of theinvention. Repeat use of reference characters throughout the presentspecification and appended drawings is intended to represent the same oranalogous features or elements of the invention.

Before any embodiments of the invention are explained in detail, it isto be understood that the invention is not limited in its application tothe details of construction or to the arrangement of components setforth in the following description or illustrated in the drawings. Theinvention is capable of other embodiments and of being practiced or ofbeing carried out in various ways.

It is to be understood that the phraseology used herein is for thepurpose of description and should not be regarded as limiting. The useof formatives of the words “include,” “comprise,” and “have” is meant toencompass the items listed thereafter and equivalents thereof, as wellas additional items.

Unless specified or limited otherwise, the terms “connected” and“carried by” are used broadly and encompass direct and indirectmountings, connections, supports, or couplings. Further, suchphraseology is not limited to physical or mechanical connections orcouplings.

As used herein, the terms “upstream” and “downstream” refer to therelative location of components in a fluid pathway. Thus, for example,in the context of a venturi in a brooder, “upstream” is relativelycloser to the fuel supply and “downstream” is relatively closer to theburner base.

As used herein, the terms “above” and “below” are with gravitationalreference. Thus, a component is “above” another if, when the presenttechnology is in regular use, that component is gravitationally higherthan the other.

A brooder 10 is disclosed. The brooder 10 includes a burner base 30, aburner cap 40, and emitter 60, a venturi 20, a baffle 50, and a canopy80.

The burner base 30 may have an upper surface 31 and an opposing lowersurface 32. The burner base 30 may define a central axis 11, the centralaxis 11 extending from the upper surface 31 to the lower surface 32.Within the upper surface 31, the burner base 30 may define a depression33. The burner base 30 may be round or of any other advantageous shape.

The burner cap 40 may be disposed above the burner base 30. The burnercap 40 may be round or of any other advantageous shape. In someembodiments, the burner cap 40 and the burner base 30 may resideadjacent to each other. The burner base 30 and the burner cap 40 maydefine between them a distribution chamber 45, in which the fuel isdistributed. In certain configurations, the burner base 30 and theburner cap 40 may define a periphery, and in some examples the peripherymay define a burner port 46 and/or 47. The burner base 30 and burner cap40 assembly may also include corrugations 43, 44 around its perimeter,forming multiple burner ports 46, 47.

In some embodiments, the burner base 30 and the burner cap 40 may beaspects of an integral burner, or a burner in which a burner base 30 anda burner cap 40 have been welded or otherwise joined together to form anintegral burner. As to those embodiments, for clarity the withindisclosure will refer to the lower aspect of such a burner as the burnerbase 30 and the upper aspect of such a burner as the burner cap 40, itbeing understood that the burner so configured is nevertheless integraland/or welded or otherwise joined together. Further, in some examples ofthose embodiments, burner ports 46 and/or 47 may be molded, drilled, orotherwise made proximate to or about the periphery of such a burner.

As described herein, a burner port 46 and/or 47 is an aperture definedin the burner through which the fuel and air mixture may pass from theinterior of the burner to the exterior of the burner.

The emitter 60 may have an inner surface 64 and an outer surface 63.Likewise, the emitter 60 may have an upper edge 61 and an opposing loweredge 62. The lower edge 62 may reside proximate to the burner cap 40 andthe burner base 30. In some instances, the emitter 60 may be shaped asan inverted frustoconical, but other shapes may be used as beneficial inother instances.

The venturi 20 is also sometimes referred to as a mixing tube. Theventuri 20 may be understood to have an upstream end 21 and a downstreamend 22. Fuel is introduced into the venturi 20 at the upstream end 21,and mixes with ambient air that is drawn into the venturi 20 at theupstream end 21. The venturi 20 may be of any length adequate to allowsufficient mixing of the fuel and air between the upstream end 21 andthe downstream end 22. The venturi 20 may also define one or morecross-sections along its length, including round, oval, elliptical,square, polygonal, curvilinear, or any combination of two or more of theforegoing.

Along its length, the venturi 20 may be straight, or curved, or of anyother shape or combination of shapes, depending on the needs of theparticular application.

The venturi 20 may reside, at least in part, below the burner base 30.Its downstream end 22 may be disposed proximate to the lower surface 32of the burner base 30. In some instances, the venturi 20 downstream end22 may be attached directly to the burner base 30, and in otherinstances it may be attached indirectly to the burner base 30; in eitherinstance, the venturi 20 may be attached to the burner base 30 at anyangle.

The venturi 20 may be in fluid communication with the burner base 30. Inparticular embodiments, the venturi 20 may be in fluid communicationwith the burner base 30 at the central axis 11.

The venturi 20 extends away from the central axis 11 at least in part inwhat may be defined as a first direction.

The venturi 20 may define a fuel flow path 25 between the upstream end21 and the downstream end 22. The fuel flow path 25 may extend, at leastin part, away from the central axis 11. Selective, nonlimitingillustrations provide the fuel flow path 25 residing at least partiallyat an angle divergent from the central axis 11. Other examples includefuel flow path 25 residing at least in part radial to the central axis11, the radiant 12 defining a first polar direction 27 from the centralaxis 11. Certain configurations provide that the fuel flow path 25resides at least partially at one or more of an acute angle, aperpendicular angle, and an obtuse angle to the central axis 11.

A venturi 20 mounting arm 23 may also be provided, for attachment ofother devices.

A venturi 20 orifice adaptor mount 24 may also be included, and adaptedfor receipt of an orifice adaptor 70 at the distal end of the burnertube 91.

The baffle 50 may be of polygonal shape, a curvilinear shape, U-shaped,V-shaped, inverted U-shaped, inverted V-shaped, asymmetrical, or anycombination of two or more of the foregoing, as found useful inparticular applications. In some uses, the baffle 50 may be at leastpartially planar. In particular examples, the baffle 50 may be at leastpartially planar and the at least partial plane may be perpendicular toa radiant 12 from the central axis 11. In some examples, the baffle 50may be at least partially planar and the at least partial plane may beparallel to the central axis 11.

In a specific example, the baffle 50 may be rectangular. Certain uses ofa baffle 50 may also include first and second chamfers 55, 56 of thebaffle 50. In particular configurations, the upper corners of the baffle50 may be chamfered. In all such instances, the chamfers 55, 56 may belinear, polygonal, curvilinear, or irregular, as particular uses maydeem advantageous.

The baffle 50 may include one or more opening through the baffle 50.Some configurations provide that the one or more opening resides lowerin the baffle 50. In a particular configuration, the one or more openingmay reside at the bottom of the baffle.

Certain baffles 50 may include a first leg 52, and other baffles 50 mayinclude a first leg 52 and a second leg 53. Other baffles 50 may beunderstood to include one or more panels 51.

The baffle 50 may be positioned anywhere inside the distribution chamber45, including proximate the downstream end 22 of the venturi 20 at theburner base 30. In some designs, the baffle 50 may reside in thedepression 33 in the burner base 30. The baffle 30 may reside proximatethe upper surface 31 of the burner base 30. Some examples locate thebaffle 50 in the distribution chamber 45 between the central axis 11 andthe periphery.

The baffle 50 may be oriented at any angular orientation. Depending onthe application, (a) the baffle 50 may be at least partially parallel tothe central axis 11, (b) the baffle 50 may be perpendicular to at leasta portion of the burner base 30; and/or (c) the baffle 50 may reside inthe distribution chamber 45 apart from the central axis 11 in the firstdirection from the central axis 11 defined by the venturi 20.

Some designs include the baffle 50 having a panel 51, the panel 51 beingat least partially planar, and the at least partial baffle 50 plane isdisposed perpendicular to a radiant 12 extending between the centralaxis 11 and the periphery.

Regarding attachment, the baffle 50 may be attached to the burner base30. It may be attached to the upper surface 31 of the burner base 30.Still further, it may be attached to the upper surface 31 of the burnerbase 30 at a location in the first polar direction 27 from the centralaxis 11 defined by the venturi fuel flow path 25.

In a certain example, the baffle 50 is rectangular and includes firstand second linear chamfers 55, 56 at its opposing upper corners. Thebaffle 50 also has a lower opening 57 disposed between two legs 52, 53that are attached to the burner base 30 within the depression 33. Thebaffle 50 is at least partially parallel to the central axis 11, isperpendicular to at least a portion of the burner base 30; and residesin the distribution chamber 45 apart from the central axis 11 in thefirst direction from the central axis 11 defined by the venturi 20. Thebaffle 50 is disposed perpendicular to a radiant 12 extending betweenthe central axis 11 and the periphery, and resides directly verticallyabove the centerline of the venturi 20. Flow of the fuel/air mixture hasbeen found to be tightly controlled and precisely delivered by use ofthis design, including the baffle of this design, in providing anoptimum symmetrical pattern to the burner ports 46, 47, by interactionof the mixture with the functionality of the baffle 50 as so configured.The resulting flames at the burner ports 46, 47 is thus uniform inheating of the emitter 60. The brooder 10, with the baffle so configuredand positioned, is functional even with different fuels, such as naturalgas, propane, butane, and liquefied petroleum gas.

Other components of the brooder 10 may include a control box 92 and gasvalve 95 for controlling the function of the brooder 10, the gas valve95 regulating the flow of fuel to the brooder 10 and the control box 92directing the gas valve 95. The control box 92 may be entirely manuallyoperated, or it may be entirely automatic (including with timers forgiven fuel supply chronologies, or both). A burner tube 91 may have avalve end 911 attached to the gas valve 95, in some instances with acompression fitting 94, and an orifice end 912 residing proximate theupstream end 21 of the venturi 20, conveying fuel to the venturi 20. Anorifice adapter 70 may be included at the downstream end 912 of theburner tube 91; different sized orifices may be used or switched withorifice adaptor 70, to provide optimal functionality of the brooder 10depending on the type of fuel used, such as natural gas, propane,butane, and liquefied petroleum gas—different sized orifice adaptors 70may be used with each type of fuel. An air restrictor cup 90 may bepositioned at the upstream end 21 of the venturi 20, optionallyincluding one or more apertures such as apertures 901, 902, to allowtuning of the fuel/air mixture as a function, for example, ofatmospheric or other conditions. An electrode 93 may reside at or nearthe burner base 30/burner cap 40 periphery, for igniting the fuel/airmixture, the electrode 93 being electrically energized by an ignitioncable 96; in other examples of the present technology, a pilot light(not shown) may instead be included in place of the electrode 93 and theignition cable 96. The brooder 10 may include a manifold support bracket97 and a label plate holder 98. A hanging bracket 99 may be included atthe top of the brooder 10, to facilitate suspending the brooder 10.

The appended drawings illustrate embodiments of the brooder 10 of thepresent invention. FIGS. 1 and 2 illustrate various such components. Asdepicted in FIGS. 1 and 2 , a central axis 11 is defined. In theembodiment illustrated in FIGS. 1 and 2 , the emitter 60 has an invertedfrustoconical shape. The emitter 60 has an outer surface 63, an upperedge 61, and an opposing lower edge 62 (see FIG. 3 ). The venturi 20 hasan upstream end 21 and a downstream end 22, and resides at least in partbelow the burner base 30. Its downstream end 22 is disposed proximate tothe lower surface 32 of the burner base 30 (not shown). Along itslength, the venturi 20 in this embodiment is straight proximate theupstream end 21, straight along its middle, and curved in its approachto the burner base 30 (not shown). As illustrated, the venturi 20extends away from the central axis 11 at least in part in what may bedefined as a first direction.

Other components of the brooder 10 are also illustrated in FIGS. 1 and 2, including a control box 92 and gas valve 95. A burner tube 91 isattached to the gas valve 95, with an orifice end 912 end residingproximate the upstream end 21 of the venturi 20. An air restrictor cup90 is positioned at the upstream end 21 of the venturi 20, includingapertures 901, 902. The brooder 10 includes a manifold support bracket97 and a label plate holder 98. A hanging bracket 99 is included at thetop of the brooder 10, to facilitate suspending the brooder 10 fromoverhead.

FIGS. 3 and 4 also illustrate various components of embodiments of thebrooder 10. The control box 92 and the gas valve 95 are depicted. Aburner tube 91 leads from the gas valve 95 to the venturi 20. An orificeadapter is included at the downstream end 22 of the burner tube 91, withan orifice sized to provide optimal functionality of the brooder 10depending on the type of fuel used, such as natural gas, propane,butane, and liquefied petroleum gas. An air restrictor cup 90 has beenpositioned at the upstream end 21 of the venturi 20, optionallyincluding apertures 901, 902. An electrode 93 is likewise included, forigniting the fuel/air mixture, the electrode 93 being electricallypowered by an ignition cable 96. The brooder 10 includes a manifoldsupport bracket 97 and a label plate holder 98. A hanging bracket 99positioned at the top of the brooder 10 facilitates suspending thebrooder 10 from overhead.

The venturi 20 is disposed below the burner base 30 and has an upstreamend 21 and a downstream end 22. Its downstream end 22 resides proximateto the lower surface 32 of the burner base 30. Fuel introduced into theventuri 20 at the upstream end 21 from the downstream end 22 of theburner tube 91, and mixes with ambient air drawn into the venturi 20 atthe upstream end 21 of the venturi 20. The venturi 20 in this embodimentis straight from its upstream end 21 and along its length, but curves asit nears the burner base 30.

The burner base 30 has an upper surface 31 and an opposing lower surface32. The burner base 30 defines a central axis 11, the central axis 11extending from the upper surface 31 to the lower surface 32. The burnercap 40 is disposed above the burner base 30 and resides adjacent to theburner base 30. The burner base 30 and the burner cap 40 define betweenthem a distribution chamber 45. They also define a periphery. The burnercap 40 also includes corrugations 43, 44 around its perimeter, formingmultiple burner ports 46, 47.

The emitter 60 has an inner surface 64 and an outer surface 63, an upperedge 61 and an opposing lower edge 62. The lower edge 62 residesproximate to the burner cap 40 and the burner base 30. The emitter 60 inthis example is shaped as an inverted frustoconical.

The venturi 20 is in fluid communication with the burner base 30 at thecentral axis 11. The venturi 20 extends away from the central axis 11 atleast in part in what may be defined as a first direction.

A venturi 20 orifice adaptor mount 24 is also included, and has receivedan orifice adaptor 70 at the distal end of the burner tube 91.

A baffle 50 is also included (see FIG. 4 ). The baffle 50 is positionedinside the distribution chamber 45, proximate the downstream end 22 ofthe venturi 20 at the burner base 30. In the embodiment illustrated inFIG. 4 , the baffle 50 resides in the depression 33 in the burner base30.

FIGS. 5, 6, and 7 illustrate embodiments of the burner base 30, baffle50, venturi 20, and orifice adaptor mount 24. The burner base 30 has anupper surface 31 and an opposing lower surface 32, and defines a centralaxis 11, the central axis 11 extending from the upper surface 31 to thelower surface 32. Within the upper surface 31 the burner base 30 isdefined a depression 33. The burner base 30 as illustrated is round.

The venturi 20 has an upstream end 21 and a downstream end 22. Theventuri 20 in these embodiments defines a circular cross-section alongits length. The venturi 20 is straight along its length from theupstream end 21, and turning upward near its downstream end 22. Itsdownstream end 22 is disposed proximate to the lower surface 32 of theburner base 30, in these embodiments, and is attached directly to theburner base 30. The venturi 20 is in fluid communication with the burnerbase 30 at the central axis 11.

The venturi 20 extends away from the central axis 11 at least in part inwhat may be defined as a first direction. The venturi 20 defines a fuelflow path 25 between the upstream end 21 and the downstream end 22, andthe fuel flow path 25 extends, at least in part, away from the centralaxis 11. As illustrated, for example, in FIG. 6 , the fuel flow path 25resides at least in part radial to the central axis 11, the radiant 12defining a first polar direction 27 from the central axis 11. Asillustrated, for example, in FIG. 7 , the fuel flow path 25 resides atleast partially at an angle divergent from the central axis 11. Also asillustrated, for example, in FIG. 7 , the fuel flow path 25 resides atleast partially at one or more of a perpendicular angle.

The baffle 50 in these embodiments is rectangular and at least partiallyplanar. The at least partial plane is perpendicular to a radiant 12 fromthe central axis 11. Likewise, in these embodiments the at least partialplane is parallel to the central axis 11. The baffle 50 includes firstand second chamfers 55, 56 at the upper corners of the baffle 50; thechamfers 55, 56 in these embodiments is linear. The baffle 50 alsoincludes a lower opening 57. Lower legs 52, 53 are included, and panel51 is incorporated.

The baffle 50 is positioned proximate the downstream end 22 of theventuri 20 at the burner base 30, and resides in the depression 33 inthe burner base 30. It will be noted that, in these embodiments, thebaffle 50 resides proximate the upper surface 31 of the burner base 30and is located in the distribution chamber 45 between the central axis11 and the periphery.

In the embodiments illustrated in FIGS. 5, 6, and 7 , the baffle 50 isat least partially parallel to the central axis 11, is perpendicular toat least a portion of the burner base 30, resides in the distributionchamber 45 apart from the central axis 11 in the first direction fromthe central axis 11 defined by the venturi 20, is disposed perpendicularto a radiant 12 extending between the central axis 11 and the periphery,and resides directly vertically above the centerline of the venturi 20.

The baffle 50 is attached to the upper surface 31 of the burner base 30at a location in the first polar direction 27 from the central axis 11defined by the venturi 20 fuel flow path 25.

A mounting arm 23 is provided, as is an orifice adaptor mount 24.

FIG. 8 illustrates an embodiment of the baffle 50. The baffle 50 in thisembodiment is rectangular and at least partially planar. The baffle 50includes first and second linear chamfers 55, 56 at the opposing uppercorners, as well as a lower opening 57. Lower legs 52, 53 are included,panel 51 is incorporated, and upper limit 54 is also noted.

In operation, the brooder 10 is suspended from above by use of thehanging bracket 99. Fuel supplied to the brooder 10 is regulated by thegas valve 95, as controlled by the control box 92. The fuel is conveyedvia the burner tube 91 to the upstream end 21 of the venturi 20. Thereambient air is drawn into the venturi, and the fuel/air mixture may beadvantageously controlled with the air restrictor cup 90. The fuel/airmixture flows through the venturi 20 along a fuel flow path 25 to theburner base 30 and into the distribution chamber 45 defined between theburner base 30 and the burner cap 40. Flow of the fuel/air mixture isprecisely delivered and tightly controlled, in an optimum symmetricalpattern to the burner ports 46, 47, by interaction of the mixture withthe prescribed interference of the baffle 50. The resulting flames atthe burner ports 46, 47 is thus uniform in its heating of the emitter60, providing the most advantageous performance of the brooder 10 in useof the fuel to provide heat to the flock of poultry below.

Accordingly, the brooder 10 aforedescribed provides a nonverticalventuri 20 and thus a minimized vertical profile, yet still achievinguniform heating of the emitter 60. The brooder 10 is functional evenwith different fuels, such as natural gas, propane, butane, andliquefied petroleum gas. The brooder 10 likewise maximizes the use ofexisting components, such as the canopy 80, emitter 60, burner cap 40,and burner base 30, minimizing the expense of such a design. The brooder10 has simplified, easy-to-clean components. The brooder 10 accomplishessuch functionality with a purposely configured and positioned baffle 50interacting with the fuel and air mixture flow to each burner port 46,47.

It should be appreciated that, in the above description of embodiments,various features are sometimes grouped together in a single embodiment,figure, or description for the purpose of streamlining the disclosureand aiding in the understanding of one or more of the various inventiveaspects. This method of disclosure, however, is not be interpreted asreflecting an intention that any claim requires more features than areexpressly recited in that claim. Moreover, any components, features, orsteps illustrated and/or described in a particular embodiment herein,can be applied to or used with any other embodiment. Thus, it isintended that the scope of the inventions herein disclosed should not belimited by the particular embodiments described above, but should bedetermined only by a fair reading of the claims that may issue from thebenefit of the within disclosure.

1. A low profile brooder, comprising: an emitter; a fuel supply ductdisposed at least partially nonvertically; and means for providing apredetermined heating pattern upon the emitter.
 2. The low profilebrooder of claim 1, wherein the means for providing a predeterminedheating pattern upon the emitter is means for providing a symmetricalheating pattern upon the emitter.
 3. The low profile brooder of claim 1,wherein the means for providing a predetermined heating pattern upon theemitter is means for providing uniform heating of the emitter.
 4. Thelow profile brooder of claim 1, wherein the emitter defines a centralaxis and the fuel supply duct resides at least in part radial to thecentral axis.
 5. The low profile brooder of claim 1, wherein the emitterdefines a central axis, the fuel supply duct resides at least in partradial to the central axis, the radiant defines a first polar directionfrom the central axis, and in which the means for providing apredetermined heating pattern upon the emitter is disposed at a locationin the first polar direction from the central axis.
 6. The low profilebrooder of claim 1, wherein the emitter defines a central axis and thefuel supply duct resides at least in part perpendicular to the centralaxis.
 7. The low profile brooder of claim 1, wherein the emitter definesa central axis, the fuel supply duct resides at least in partperpendicular to the central axis, the radiant defines a first polardirection from the central axis, and in which the means for providing apredetermined heating pattern upon the emitter is disposed at a locationin the first polar direction from the central axis.
 8. A method ofincreasing the interior temperature of a poultry house, comprising thesteps of: providing the low profile brooder of claim 1; providing a fuelto the fuel supply duct; and igniting the fuel within the low profilebrooder.
 9. A low profile brooder, comprising: a distribution chamberthat defines at least two burner ports; a fuel flow path extending atleast in part nonvertically away from the distribution chamber; and abaffle residing in the distribution chamber, the baffle including meansto equalize the fuel velocities at each of the at least two burnerports.
 10. The low profile brooder of claim 9, in which the means toequalize the fuel velocities at each of the at least two burner portsincludes at least one of the relative location of the baffle within thedistribution chamber, a lower opening, a first chamfer, and a secondchamfer.
 11. The low profile brooder of claim 9, in which thedistribution chamber defines a central axis, the fuel flow path extendsupstream away from the distribution chamber at least in part in a firstdirection, and the baffle resides apart from the central axis in thefirst direction.
 12. The low profile brooder of claim 9, in which thedistribution chamber defines a central axis and the baffle is at leastpartially planar, the at least partial plane being parallel to thecentral axis.
 13. A method of increasing the interior temperature of apoultry house, comprising the steps of: providing the low profilebrooder of claim 9; providing a fuel to the fuel supply path; andigniting the fuel within the low profile brooder.
 14. A method ofincreasing the interior temperature of a poultry house, comprising thesteps of: providing the low profile brooder of claim 9; providing anorifice adaptor configured for a specific fuel and connecting theorifice adaptor to the upstream end of the fuel supply path; providing asource of the specific fuel to the fuel supply path; and igniting thefuel within the low profile brooder.
 15. A low profile brooder,comprising: a venturi, a distribution chamber, at least two burnerports, and a baffle; the distribution chamber in fluid communicationwith at least two burner ports; the venturi: in fluid communication withthe distribution chamber; having an upstream end and a downstream end;defining a fuel flow path between the upstream end and the downstreamend, the fuel flow path residing at least partially at one or more of anacute angle, a perpendicular angle, and an obtuse angle to vertical; andthe baffle residing in the distribution chamber between the downstreamend and the at least two burner ports.
 16. The low profile brooder ofclaim 15, in which the distribution chamber defines a central axis andthe venturi resides at least in part radial to the central axis.
 17. Thelow profile brooder of claim 15, in which the distribution chamberdefines a central axis and the venturi resides at least in part radialto the central axis, the radiant defining a first polar direction fromthe central axis, and the baffle resides in the first polar directionfrom the central axis.
 18. The low profile brooder of claim 15, in whichthe baffle includes at least one of a lower opening, a first chamfer,and a second chamfer.
 19. The low profile brooder of claim 15, in whichin which the distribution chamber defines a central axis, the baffle isat least partially planar, and the at least partial plane is orientedperpendicular to a radiant extending from the central axis.
 20. The lowprofile brooder of claim 15, in which the baffle includes means forproviding uniform heating of the emitter.